Upload
phamdang
View
216
Download
0
Embed Size (px)
Citation preview
Batley, R., Bates, J., Bliemer, J., Borjesson, M., Bourdon, J., Cabral,M. O., Chintakayala, P. K., Choudhury, C., Daly, A., Dekker, T.,Drivyla, E., Fowkes, T., Hess, S., Heywood, C., Johnson, D., Laird,J., Mackie, P., Parkin, J., Sanders, S., Sheldon, R., Wardman, M. andWorsley, T. (2017) New appraisal values of travel time saving and re-liability in Great Britain. Transportation. ISSN 0049-4488 Availablefrom: http://eprints.uwe.ac.uk/33201
We recommend you cite the published version.The publisher’s URL is:http://dx.doi.org/10.1007/s11116-017-9798-7
Refereed: Yes
(no note)
Disclaimer
UWE has obtained warranties from all depositors as to their title in the materialdeposited and as to their right to deposit such material.
UWE makes no representation or warranties of commercial utility, title, or fit-ness for a particular purpose or any other warranty, express or implied in respectof any material deposited.
UWE makes no representation that the use of the materials will not infringeany patent, copyright, trademark or other property or proprietary rights.
UWE accepts no liability for any infringement of intellectual property rightsin any material deposited but will remove such material from public view pend-ing investigation in the event of an allegation of any such infringement.
PLEASE SCROLL DOWN FOR TEXT.
New appraisal values of travel time saving and reliabilityin Great Britain
Richard Batley1• John Bates2
• Michiel Bliemer3•
Maria Borjesson4• Jeremy Bourdon5
• Manuel Ojeda Cabral1 •
Phani Kumar Chintakayala1• Charisma Choudhury1
•
Andrew Daly1• Thijs Dekker1
• Efie Drivyla5•
Tony Fowkes1• Stephane Hess1
• Chris Heywood6•
Daniel Johnson1• James Laird1
• Peter Mackie1•
John Parkin7• Stefan Sanders5
• Rob Sheldon6•
Mark Wardman1• Tom Worsley1
� The Author(s) 2017. This article is an open access publication
Abstract This paper provides an overview of the study ‘Provision of market research for value
of time savings and reliability’ undertaken by the Arup/ITS Leeds/Accent consortium for the
UK Department for Transport (DfT). The paper summarises recommendations for revised
national average values of in-vehicle travel time savings, reliability and time-related quality
(e.g. crowding and congestion), which were developed using willingness-to-pay (WTP)
methods, for a range of modes, and covering both business and non-work travel purposes. The
paper examines variation in these values by characteristics of the traveller and trip, and offers
insights into the uncertainties around the values, especially through the calculation of confi-
dence intervals. With regards to non-work, our recommendations entail an increase of around
50% in values for commute, but a reduction of around 25% for other non-work—relative to
previous DfT ‘WebTAG’ guidance. With regards to business, our recommendations are based
on WTP, and thus represent a methodological shift away from the cost saving approach (CSA)
traditionally used in WebTAG. These WTP-based business values show marked variation by
distance; for trips of less than 20 miles, values are around 75% lower than previous WebTAG
values; for trips of around 100 miles, WTP-based values are comparable to previous WebTAG;
and for longer trips still, WTP-based values exceed those previously in WebTAG.
& Richard [email protected]
1 Institute for Transport Studies, University of Leeds, Leeds LS2 9JT, UK
2 John Bates Services, Abingdon, UK
3 Institute of Transport and Logistics Studies, University of Sydney, Sydney, Australia
4 Centre for Transport Studies, Royal Institute of Technology, Stockholm, Sweden
5 Arup, London, UK
6 Accent, London, UK
7 Centre for Transport and Society, University of West of England, Bristol, UK
123
TransportationDOI 10.1007/s11116-017-9798-7
Keywords Value of travel time savings � Value of reliability �Value of crowding � Value of congestion � Business � Non-work
Introduction
This paper provides an overview of the study ‘Provision of market research for value of
time savings and reliability’ undertaken by the Arup/ITS Leeds/Accent consortium for the
UK Department for Transport (referred to henceforth as the ‘Department’). Whilst the full
technical reports of the study (Arup, ITS Leeds and Accent 2015a, b) are already in the
public domain, and the study team’s recommendations have largely been accepted and
implemented by the Department (DfT 2015, 2016, 2017), the present paper seeks to present
a digestible summary that is accessible to a broad academic readership.
In the context of transport appraisal, one of the most important concepts is that con-
ventionally referred to as the ‘value of time’. This does not refer to the value that might be
placed on time spent in travel, but should be seen as shorthand for the ‘value of changes in
travel time’, relative to a reference case when investment takes place. These changes may
be positive or negative, but historically have been referred to as ‘savings’. Travel time
savings are usually the largest single component of the monetised benefits of transport
infrastructure projects and policies. Furthermore, time-related benefits such as reliability
and relief of overcrowding on public transport (PT) are conventionally valued through
multipliers on the ‘value of time’. In this paper we have chosen to refer to the ‘value of
travel time’ (VTT) to convey this concept.
There have been three waves of national studies of VTT in Britain. First, a series of
research studies during the 1960s, the results of which were synthesised and adopted by the
Department in appraisal guidance. Second, the MVA, ITS Leeds and TSU Oxford (1987)
study, which led to updated guidance. Third, the 1994 study by Accent and Hague Con-
sulting Group (published some years later as AHCG 1999), which was re-analysed by ITS
Leeds (Mackie et al. 2003) before again being committed to guidance. Between 2003 and
2016, appraisal guidance was intermittently revised and updated by the Department, to
reflect changes in incomes and travel patterns [e.g. as documented in WebTAG1 Unit A1.3
(DfT 2014)]. The underpinning behavioural estimates of VTT were not however re-sur-
veyed. In other words, between 2003 and 2016, appraisal guidance on VTT was based on
survey data collected in 1994, and analysed using methods considered best-practice in
2003.
Over the subsequent 20 years, incomes, prices, demography and the mix of travel by
purpose and trip length have all changed. Possibly more significant is that the world has
moved on in other ways—the internet revolution, the quality and comfort of vehicles,
working practices and, perhaps most fundamentally, the ways in which people perceive
time spent travelling. It does not seem credible to suggest that such phenomena can be
accommodated simply through updating historical behavioural values for changes in
incomes and travel patterns. Also, over the same period, there have been developments in
methods for collecting survey data and estimating VTT measures. Contrasting 2016 best-
practice against 2003, we are now better equipped to understand various empirical phe-
nomena such as variability in VTT (e.g. ‘deterministic’ variation across different travel
1 WebTAG is an acronym for Web-based Transport Analysis Guidance. This resource is developed andpublished by the Department, and contains official ‘‘guidance on the conduct of transport studies’’ in theUK.
Transportation
123
conditions, travellers and trip types, as well as inherently ‘random’ or ‘unobserved’
variation), discontinuities in VTT (e.g. ‘size’ and ‘sign’ effects (de Borger and Fosgerau
2008), as well as the phenomenon of ‘cost damping’ Daly 2010), and any residual
‘uncertainty’ in the resultant values (which would contribute to confidence intervals on the
VTTs used in appraisal Daly et al. 2012a).
In response to these challenges, the Department has, since 2009, taken steps to review
the theoretical, methodological and evidential basis of its VTT guidance. Among the key
actions have been the Department’s commissioning of scoping studies concerning the
valuation of travel time, for both non-work and business. The ITS Leeds, John Bates and
DTU (2010) study ‘Values of travel time savings: updating the values for non-work travel’
scoped out the research activities that would be required to update the values for non-work
travel, and issued recommendations on which packages of activities should be commis-
sioned. In a similar fashion, the ITS Leeds, John Bates and KTH (2013) study ‘Values of
travel time savings for business travellers’ reviewed the feasibility and theoretical accuracy
of different methods for estimating VTT for business travellers, as well as evidence from
the UK and overseas on the values emanating from these different methods [see also the
companion journal paper Wardman et al. (2015)].
Informed by these scoping studies, the Department commissioned new market research
to deliver updated evidence on values of travel time and reliability (DfT 2013), and the
resulting tender was awarded to the Arup/ITS Leeds/Accent consortium. The study was
conducted in two phases, across a challenging timeframe of 11 months. Phase 1 of the
study, which was undertaken from June to September 2014, involved the development and
testing of methods for undertaking the requisite market research. Phase 2 involved a
substantial field survey and detailed modelling to complete estimation of the values of
travel time using the collected data.
Study aims, scope, and delivery
The Department specified the following aims for the research:
• To provide recommended, up-to-date national average values of in-vehicle travel time
savings, covering business and non-work travel, and based on primary research using
‘‘modern, innovative methods’’.
• To investigate the factors which cause variation in the values (e.g. by mode, purpose,
income, trip distance or duration, productive use of travel time etc.) and use this to
inform recommended segmentation of the values.
• To improve our understanding of the uncertainties around the values, including
estimating confidence intervals around the recommended values.
• To consistently estimate values for other trip characteristics for which values are
derived from the values of in-vehicle time savings.
In pursuit of these aims, we employed an analysis framework based upon the primary
dimensions of trip purpose and mode of travel (see Table 1). Within this framework, key
features of the present paper include the following:
• We focus on the mechanised modes of car, bus, rail and ‘other PT’.2 The walk and
cycle research encountered significant methodological challenges, and was eventually
2 ‘Other PT’ refers to ‘other public transport’, namely trams, light rail and London Underground. By ‘rail’we mean heavy rail.
Transportation
123
Ta
ble
1S
um
mar
yo
fsu
rvey
des
ign
Mo
de
of
trav
elT
rip
pu
rpose
SP
exp
erim
ent
Cov
aria
te
Com
mu
teO
ther
no
n-w
ork
Em
plo
yee
s’b
usi
nes
sE
mp
loy
ers’
bu
sin
ess
Car
SP
SP
SP
SP
SP
1:
Tim
e(a
)In
com
e
Bus
SP
SP
N/A
N/A
SP
2:
Tim
ean
dR
elia
bil
ity
(b)
Dis
tance
/dura
tion
Rai
lS
Pan
dR
PS
Pan
dR
PS
Pan
dR
PS
PS
P3
:T
ime
and
Qu
alit
y(e
.g.
crow
din
g,
conges
tion
and
oth
erty
pes
of
tim
e)(c
)P
rod
uct
ive
tim
e
‘Oth
er’
PT
SP
SP
SP
SP
(d)
Tri
pty
pe
etc.
Wal
kan
dcy
cle
SP
SP
N/A
N/A
N/A
dee
med
not
tobe
appli
cable
on
the
gro
unds
that
trip
rate
sar
ere
lati
vel
ylo
w,
SP
Sta
ted
Pre
fere
nce
,R
PR
evea
led
Pre
fere
nce
Transportation
123
reported to the Department separately from the mechanised modes, and with only
tentative recommendations (Arup, ITS Leeds and Accent 2015b).
• Informed by the scoping studies, the Department directed us to value travel time
savings using willingness-to-pay (WTP) methods—for both non-work and business.
• The latter directive in respect of business reflected the Department’s interest in
replacing the long-standing Cost Saving Approach (CSA) (e.g. Harrison 1974) for
valuing business travel time savings with WTP—if the evidence base was adequate to
support such a change.
• Whilst the direction was to implement WTP methods primarily through Stated
Preference (SP) data, the Department encouraged us to validate the SP with Revealed
Preference (RP) data.3
• The Department directed us to examine business travel from two alternative
perspectives, namely those of the employee and employer. With regards to the latter,
the employee is effectively ‘spending’ the business’s time and money, and it is
important therefore that the employee reports a WTP representative of his/her
employer’s interests. Whilst directed to examine business using WTP, the Department
specifically excluded the so-called ‘Hensher’ equation (Hensher 1977) from our scope.
Design and implementation of the market research
This section sets out the process followed for designing and implementing the market
research. As noted in the ‘‘Introduction’’ section, the market research was focussed around
SP, but complemented by RP as a validation device. These methods were designed and
developed in a systematic fashion, involving the following steps:
1. Qualitative research was conducted in certain areas of the brief that were considered to
involve particular challenges; these areas included the valuation of business travel time
savings, the presentation of reliability, and the presentation of car use costs.
2. The prior qualitative research informed the design of the SP and RP experiments, as
well as the development of the questionnaires more generally.
3. Cognitive depth interviews tested the flow, comprehensibility and wording of the
questionnaires.
4. Pilot surveys were administered in two waves, involving testing of all data collection
and analysis methods.
5. The field survey involved a full ‘roll-out’ of the data collection and analysis methods,
exploiting lessons learned from the pilot surveys.
Whilst the aims of the study required us to conduct primary research using ‘modern,
innovative methods’, it is worth remarking that, from a theoretical perspective, we sought
to ground these methods within the standard microeconomic framework underpinning both
non-work and business VTT, as rationalised by Becker (1965), De Serpa (1971) and Evans
(1972), and as codified in Section 3.3 of MVA et al. (1987).
3 As it transpired, the RP analysis proved extremely challenging, and only limited insights could be gleanedin terms of validation of the SP; see the study report (Arup, ITS Leeds and Accent, 2015a; Chapter 5) for afull discussion. The RP survey and analysis are not discussed in this paper.
Transportation
123
Stated Preference (SP) approach
Experimental design method
Table 2 summarises the context and content of the principal SP experiments.
Presentational considerations Informed by the prior qualitative research, together with
insights gleaned from previous UK national VTT studies and the literature more generally,
it was decided to define car cost in terms of fuel cost and public transport cost in terms of
one-way ticket price. For car, we were conscious that the use of fuel cost could undermine
the realism of SP choices between faster/cheaper versus slower/dearer journeys, in the
sense that longer journeys might in practice consume more fuel and therefore be more
costly. On balance, however, it was judged that fuel costs represented the best (or least
worst, perhaps) available representation of costs, especially in a British context with very
few toll roads/bridges. For public transport travelcard users, an appropriate one way ticket
price was derived from the monthly or annual cost. The SP experiments were explicit
concerning the definition of cost for car and public transport, and the preamble instructed
Table 2 Summary of principal SP formats by game and mode
Game andmode
Description of SP format
SP1 SP1 used a generic format across all modes, presenting respondents with an ‘abstract’choice between two options described only on the basis of travel time and travel cost,where one option was cheaper, but the other option was faster
SP2 SP2 also presented respondents with an abstract binary choice, still focussing on travel costand travel time but where, for travel time, five different typical trip outcomes werepresented for each alternative as a representation of travel time variability
SP3 SP3 used somewhat different presentations across modes, whilst nevertheless retaining anabstract binary choice context, as described for each mode below
SP3 car For car, the two options were described in terms of travel cost for each trip and the amountof time that each trip spends in three types of driving conditions (free-flow, light traffic,heavy traffic)
SP3 rail For rail, two different experiments were used:
(a) For the first group, we presented a choice similar to SP1, with the difference that foreach alternative we additionally defined the level of crowding applying to the trip
(b) For the second group, we presented a choice between up to three operators, describedin terms of travel time, fare and headway
SP3 bus For bus, two different experiments were also used:
(a) For the first group, we presented a crowding game analogous to the rail game, albeitwith different crowding definitions
(b) For the second group, we presented a choice between two bus routes described interms of free-flow time, slowed down time, dwell time, headway and fare
SP3 ‘otherPT’
For ‘other PT’, two different experiments were again used:
(a) For the first group, we presented a crowding game analogous to the bus game
(b) For the second group, we presented a mode choice game (‘other PT’ against either busor rail) using time, headway and cost as attributes
Transportation
123
respondents to assume that the offered alternatives were identical in terms of other facets of
cost.
Examples of SP1-3 for car are presented in Figs. 1, 2 and 3 respectively. Given the
policy context of this research, it was judged important to remain faithful to established
UK practices for valuing time savings, reliability and quality, and this motivated the
presentations shown. Thus, Fig. 1 is essentially AHCG’s (1999) presentation which
underpinned previous WebTAG guidance on VTT, Fig. 2 is a variant of Hollander’s
(2006) presentational approach which was originally developed in the context of UK bus,
and Fig. 3 is a simplified version of the presentation employed in ITS Leeds’ (2008) after-
study of the M6 Toll. Whilst similar approaches were generally followed for public
transport, an example of SP3a for rail is also provided (Fig. 4), to illustrate the manner in
which we addressed the PT-specific issue of crowding. This is a simplification of MVA’s
(2008) presentation which underpins Passenger Demand Forecasting Handbook (ATOC
2012) guidance on crowding penalties.
We should acknowledge that, whilst commonplace in most UK and many European
studies (though not the Swiss and German studies), the presentational approaches shown in
Figs. 1, 2, 3 and 4 have been supplanted by alternative approaches in some other countries
(e.g. Australia). The approaches used here may not, therefore, be considered best practice
elsewhere, especially in terms of: (1) separating out different time components across
different SP games; (2) the means of presenting reliability; and (3) the reliance on binary
choice tasks only. However, a strong reason for using these approaches is that they
facilitated objective comparison—on a like-for-like basis—of updated values against
previous WebTAG and PDFH values.
Exceptions to the formats described in Table 2 included SP experiments focussed upon
public transport mode choice (involving separate games for concessionary and non-con-
cessionary travellers) and rail operator choice (corresponding to the RP context). In most
cases (exceptions being walk and cycle and bus concessions), respondents received all
three SP games (i.e. SP1, SP2 and SP3). SP1 was presented always presented first, whilst
the ordering of SP2 and SP3 was randomised in order to mitigate ‘order effects’.
Statistical considerations The SP designs for this study were based upon the concept of
Bayesian D-efficiency, which has the potential to give more precise (in terms of reduced
standard errors) parameter estimates when used appropriately (Rose and Bliemer 2014).
Whilst it was clear that different designs would be needed for different games (e.g. SP1–3),
we also recognised that efficient designs needed to be optimised for the specific values of
attributes and priors of interest. This had two separate dimensions in the present context.
Firstly, as substantial differences in values of time (and other valuations) were expected
to exist between business and non-business travellers, separate designs were produced for
these two purpose segments. In essence, this means that the trade-offs presented to business
Fig. 1 Time versus cost experiment (SP1) for car
Transportation
123
travellers were geared towards their likely higher willingness-to-pay, thereby giving us
more robust estimates in the analysis.
Secondly, the surveys presented respondents with trips framed (or ‘pivoted’ in exper-
imental design terms) around the travel time and (monetary) cost of a recent trip they had
made. Additionally, the percentage variations in travel time and cost around the reference
trip were varied with trip characteristics. Simply using a generic design—in terms of
percentage variations—across all trip types, could have incited a major loss of efficiency.
Fig. 2 Time versus cost versus reliability experiment (SP2) for car
Fig. 3 Time versus cost versus quality experiment (SP3) for car
Fig. 4 Time versus cost versus quality experiment (SP3) for rail
Transportation
123
Separate designs were produced for a set of representative trips. Each respondent was
then given a design based on the trip closest to their reference trip (in terms of the smallest
percentage difference between the reference values for the design and that respondent’s
values for time and cost), with percentage variations (or pivots) applied to the specific
reference trip for that person, where these pivots were obtained from the design.
The number of reference trips used varied by mode, with the lowest number for bus (2)
and the highest number for rail (20). Each SP game presented a respondent with five
separate choice scenarios. The actual designs made use of a number of rows that was larger
than the number of tasks assigned to a single respondent, to ensure sufficient richness in the
variations in the data. As an example, for car SP1, the boundary value of times ranged from
£0.15/hour to £372/hr. This was of course partly a result of some very cheap and very
expensive reference trips, but even when looking at the reference trips used in the design
process, the range extended from £0.45/hr to £90/hr. The overall design was then split into
a number of distinct blocks at the design stage, minimising correlation between attributes
and blocks, and each block was used as closely as possible a uniform number of times
across the sample of respondents. The number of rows for designs was set to 25 after
extensive testing. In total, 315 designs were produced for this study.
The subsequent discussion details the inputs used in all designs and explains how the
design outputs were used to compute the values presented to respondents. We also look at
any additional constraints imposed on the designs, where it should be noted that, by
default, the design approach already avoided scenarios in which one alternative was
dominated, e.g. there was no possibility in the simple time-money trade-offs that one
option was both faster and cheaper than the other.
Car games
• No additional constraints were imposed on SP1 given the above mentioned avoidance
of dominance.
• For SP2, and for reasons of realism, we excluded cases where either the shortest travel
time or the highest travel time was combined with the highest level for travel time
variability.
• For SP3, we imposed additional constraints which guaranteed that the implied distances
for the two trips differed by no more than 25%, again for reasons of realism (assuming
that light traffic speed would be 80% of free-flow, and heavy traffic speed would be
60% of free-flow). The design allowed for both increases and decreases around
reference values, and the design process sought to achieve attribute level balance, i.e.
guaranteeing that increases were as likely as decreases. We introduced some flexibility
into this process, by allowing the share of increases and decreases to be different from
50/50, which in turn allowed the constraints on the total sum to be met.
• For all games, we defined an adjusted free-flow reference time (AFF) on the basis of the
current free-flow time (CFF) and current total time (CTT) as:
AFF ¼ CFF þ max 0;� CFF þ min DFFð Þ � CTTð Þð Þ
Here, min (DFF) was the smallest (i.e. most negative) additive percentage shift used for
free-flow time across both alternatives and across all five tasks for the respondents. This
meant that the adjusted free-flow was shifted upwards for all tasks and all alternatives in
those cases where any of the alternatives in any of the tasks would have required censoring.
We then used the definition:
Transportation
123
FF ¼ AFF þ DFF � CTT
to compute the values to be presented.
Rail games
• No additional constraints were imposed on any of the designs.
Bus games
• No additional constraints were imposed on SP1 or SP2.
• For SP3a, we imposed additional constraints which guaranteed that the implied
distances for the two trips differed by no more than a third, again for reasons of realism
(assuming that slowed down time speed would be 50% of free-flow).
• No additional constraints were imposed on SP3b.
‘Other PT’ games
• No additional constraints were imposed on any of the designs.
General public SP market research method
The core research method for the SP survey was intercept recruitment (80% of recruits)
followed by on-line or telephone interviews; this was supplemented by telephone
recruitment (20%) again with on-line or telephone completion.
Taking the NTS 2010-12 dataset as the benchmark for representativeness, 80% of all
recorded trips cover less than 10 miles. However, many studies have found a strong
relationship between VTT and distance (e.g. Mackie et al. 2003), and as we subsequently
use distance weighting to derive appraisal values (see the ‘‘Appraisal values’’ section), it is
important to be able to estimate VTT for longer trips accurately. Using the NTS definition
of ‘long distance’ (i.e. greater than 50 miles), only 2% of trips in the NTS fall into this
category. A telephone sampling approach predominantly samples short distance trips. On
the other hand, an intercept sampling approach, as has been conventional in most VTT
studies, favours longer distance trips, since these have a higher probability of being
intercepted. Balancing these considerations, the chosen approach was two-pronged: pre-
dominantly using intercepts to ensure an adequate sample of the longer distance move-
ments, and more generally business trips, but using telephone sampling to strengthen the
sample in the shorter distances. An exception to this approach was ‘other PT’, which was
recruited through intercept only, given the limited usage of this mode outside of London.
Another attraction of the intercept approach is that interviewers can be located where
the target respondents are (e.g. at bus stops, rail stations and motorway service areas). This
was particularly important to be able to recruit adequate samples of specific groups of
target respondents who would otherwise be extremely difficult to recruit through other
sampling approaches (e.g. those making specific ‘other PT’ and bus trips on corridors
where there was a rail alternative (required for the operator choice SP exercise); those
making trips on specific rail routes (to provide comparisons with the RP sample); long
Transportation
123
distance car and rail travellers; employees’ business travellers; or those no longer having a
landline phone).
Intercept recruitment The intercept CAPI4 survey was administered face-to-face using
Android tablets. Interviewers approached a random sample of adults (typically 1 in 3) and
asked scoping questions to check whether each respondent was in-scope and matched
required quotas. If in-scope, the respondent was invited to undertake a follow-up survey
either on-line or by phone. The interviewer collected their contact details (name and
telephone number for follow-up telephone interview, and name and e-mail address for
follow-up on-line survey). All intercept fieldwork took place on weekdays with fieldwork
shifts either 07:00–13:00 or 13:00–19:00. Figure 5 shows the intercept locations, which
were designed to cover car, rail, bus and ‘other PT’ users across the country.
The survey locations were selected to reflect:
• Coverage of the key trip purposes.
• A reasonable geographical spread across England, some coverage in Scotland, as well
as some cross-border flows into Wales.
• A reasonable spread of the key market segmentations relevant to each mode.5
• Specific locations where travellers had a real opportunity to choose between different
trips with different times, costs, reliability and/or quality features.
Bus concessionary passholders were only sampled in Sheffield, Leeds, Bristol and
Brighton, since these areas provide bus travel at zero cost to passholders and rail travel at
non-zero cost, and on bus routes with a parallel rail route, so that a bus versus rail SP
exercise could be undertaken. In the case of ‘other PT’, most respondents (except those
sampled in London Underground central locations) were sampled on routes towards the
centre (along a rail or bus route), so that a bus or rail versus ‘other PT’ SP exercise could be
undertaken.
Telephone recruitment For the general public telephone sample, Random Digit Dialling6
(RDD) sample was purchased that geographically represented the population of England as
shown in the 2011 Census by region. Given that mobile numbers are not geographically
specific; the requirement for geographical representativeness effectively forced us to sur-
vey residential landline numbers. We acknowledge that the exclusion of mobile numbers
could have introduced a degree of socio-economic and/or demographic bias, since landline
users tend to be older and more affluent, all else equal. That said, these biases would have
been partly mitigated by the intercept recruitment.
Adult respondents were contacted and screened using a recruitment questionnaire and, if
in-scope, they were invited to participate in the research either on-line or by phone. The
former were sent a web-link to the customised survey using the same e-mail invite as for
the intercept survey. For those who undertook the whole interview by phone, the SP
4 Computer aided personal interview.5 Ensuring that, for example, rail included flows such as London long, non-London long, South East outer,South East inner, car included inter-urban, urban and rural, and bus included London, Metropolitan/PTE,freestanding large urban areas and market towns/rural hinterland.6 RDD sample is created by selecting a known existing number, and randomising the last couple of digits togenerate a new telephone number that may or may not exist, and may or may not be a residential number.This is checked using a pulsing machine to dial the resulting phone numbers, and tell at the exchangewhether the number is valid or not.
Transportation
123
options for the three exercises (i.e. SP1–3) were sent electronically or in hard copy. Since
these exercises were customised to the responses from preliminary questions, the practical
implication was that around a third of the CATI7 interviews needed to be paused and
reconvened at a later time and/or date, once the SP options had been dispatched to the
respondent. The telephone fieldwork was undertaken between 14:00 and 21:00 Monday to
Friday, between 10:00 and 18:00 Saturday, and between 11:00 and 19:00 Sunday, to help
ensure that those in employment could be recruited.
Fig. 5 Maps of the sampling locations for rail, car, bus and ‘other PT’
7 Computer aided telephone interview.
Transportation
123
Employers’ business SP approach
One of the aims of this study, which distinguished it from previous UK VTT studies, was to
gather comprehensive evidence on VTT for business trips. This required evidence from the
perspectives of both employees and employers. For the latter, we focussed upon so-called
‘briefcase’ travel,8 and deliberately omitted operational functions undertaken by the likes
of service engineers, travelling sales forces, delivery agents etc. Mindful that employers’
business data can be difficult and costly to collect, we judged that survey resources were
best directed at this key business traveller segment (see later discussion in the ‘‘Recon-
ciling different sources of evidence on business values’’ section).
Experimental design method
The SP design method was exactly the same as for the general public survey, with the
exception that experiment was administered to the employer, but framed around a hypo-
thetical trip undertaken by an employee using car, train or ‘other PT’.
Employers’ business SP market research method
The surveys were administered by telephone, and the target respondent was ‘‘the person
within the company who was responsible for making decisions about how employees travel
for business purposes, for example when travelling to meet clients, customers or suppliers
or when travelling between different offices within their organisation’’. In smaller com-
panies this could be the owner, managing director, finance director, operations manager,
procurement manager or HR manager. In larger companies, there are often many such
people, provoking the concern that responses may be dependent on the specific person
interviewed. However, we drew reassurance from the fact that definitive travel policies
were more prevalent in larger companies; in our sample, 77% of companies with over 250
employees had formal travel policies, as compared to 23% for companies with less than 20
employees. Respondents were sent the three SP exercises (i.e. SP1–3), which were cus-
tomised based on various answers within the questionnaire.
The telephone sample was supplied by Sample Answers and used LBM Direct Mar-
keting and Experian Business Files, which in turn were based on data from Thomson
Directories and Companies House. Telephone numbers were randomly drawn from this
sample.
In addition to quotas on the mode used by the employee for the hypothetical trip (133
car, 133 rail and 133 ‘other PT’), there were quotas on company size, industry grouping
and region. Company size quotas were determined in discussion with the Department, with
a view to ensuring adequate coverage of all industry groupings, whilst also focussing
survey effort on larger companies undertaking ‘briefcase’ travel.
Incentives
All participants were offered a £10 incentive (an Amazon or Boots voucher or a donation
to a charity) on completion of the main questionnaire. Towards the end of the fieldwork
period, some participants were offered a £20 incentive to help meet certain quotas. In total,
8 For the purposes of this study, briefcase travel was defined as ‘‘trips made by office-based staff travellingto conduct meetings and similar business activities but not to provide trade services’’.
Transportation
123
3% of the general public sample and 25% of the employers sample received £20. For
employers, these participants were more likely to be rail users and from larger companies,
as these were the quota groups that were being targeted at this stage of the survey.
Implementation of field surveys
Fieldwork took place between 24th October and 15th December 2014. The latter date was
a ‘hard’ deadline agreed with the Department, so as to avoid conducting survey work
during the Christmas and New Year period, when travel behaviour might be atypical.
Whilst the final report of the study (Arup, ITS Leeds and Accent 2015a; Chapter 3) pro-
vided a comprehensive description of the features of the travellers and trips surveyed, the
following sub-sections focus discussion on the success of the fieldwork against the target
sample sizes.
General public SP survey
With reference to Table 3, 8623 SP interviews were undertaken with the general public,
against an overall target of 8500. The number of interviews exceeded both the overall
target, and most of the mode/purpose segment targets. The shortfall for some targets,
particularly ‘other PT’ employees’ business and bus commuting, were due to a shortage of
business/commute travellers at the survey locations identified for those modes.
89% of the car, rail and bus SP interviews were intercept-recruited and 11% CATI-
recruited. ‘Other PT’ interviews were all intercept-recruited. The proportion recruited by
phone was rather lower than the 20% target, mainly because bus and rail commute and
employees’ business respondents were found to be relatively scarce. The car sample was
19% CATI-recruited (predominantly commute and non-work). It should be noted that any
residual bias in trips/travellers in the sample was corrected at the implementation stage (as
discussed in the ‘‘Appraisal values’’ section).
84% of the SP interviews were undertaken on-line and 16% by telephone. 45% of the
SP interviews were completed within a day of recruitment and a further 33% two to seven
days after recruitment. Of those who were intercept-recruited, 91% completed the ques-
tionnaire on-line and 9% undertook the interview by telephone. Conversely, of those who
were CATI-recruited, 90% completed the questionnaire by telephone and 10% completed
the questionnaire on-line.
Table 3 Total completed SP interviews (on-line and CATI) by mode and purpose (targets in parentheses)
Mode Commute Other non-work Employees’ business Total
Car (1000) 1032 (1000) 1037 (1000) 956 (3000) 3025
Bus (500) 371 (500) 672 (0) N/A (1000) 1043
Rail (1000) 998 (1000) 1128 (1000) 1010 (3000) 3136
‘Other PT’ (500) 614 (500) 540 (500) 265* (1500) 1419
Total (3000) 3015 (3000) 3377 (2500) 2231 (8500) 8623
* Includes 22 bus
Transportation
123
Employers’ business SP survey
With reference to Table 4, the target of 400 employers’ business interviews was achieved,
although there was a shortfall on the largest businesses.
Recruitment and response rates
To give an indication of the success of the recruitment approach, Tables 5 and 6 show the
total number of ‘contacts’ for the general public SP survey, with breakdown by those
contacts recruited and those ‘lost’ for one reason or another. As might be expected, the
intercept-based approach—which targeted existing users of specified modes—was con-
siderably more successful in recruiting respondents (71% on average) as compared with the
telephone-based approach (6%)—which simply entailed random sampling of residential
landlines.
Table 4 Total SP interviews(CATI completion) by mode andnumber of employees (targets inparentheses)
* ‘Other PT’ dropped, remaininginterviews split between rail andcar (agreed revised minimum forrail of 130)
Target Actual
Mode
Car (194–257)* 244
Train (130–194)* 143
‘Other PT’ N/A 13
Number of employees
1–19 (67) 74
20–49 (67) 73
50–249 (133) 149
250? (133) 104
Total (400) 400
Table 5 General public SP sur-vey intercept recruitment
Total % Bus % Rail % Car % ‘Other PT’ %
Recruited 71 72 79 62 76
Refusals 11 19 6 16 14
Drop-outs 2 3 2 3 2
Out-of-scope 15 6 13 19 7
Sample size 39,475 3757 9993 10,403 5462
Table 6 General public SP sur-vey telephone recruitment
Total %
Recruited 6
No reply/answerphone 50
Refusal 31
Number not recognised/fax/business etc 8
Out-of-scope 4
Sample size 31,960
Transportation
123
For the intercept-recruited respondents as a whole (i.e. across all surveys), the overall
response rate was 37%. Of those recruited, 93% supplied an e-mail address for the on-line
survey, whilst 7% supplied a phone number for the follow-up telephone survey; the
response rate was the same for both approaches. For the CATI-recruited respondents as a
whole, the response rate was 61% for those who were in-scope and recruited.
Choice modelling
The remainder of this paper will devote particular attention to the general public SP dataset
since, as we will see in the ‘‘Appraisal values’’ section, this dataset formed the basis of the
appraisal values of travel time and reliability eventually recommended to the Department.
The RP and employers’ SP datasets were used principally to validate and corroborate the
general public SP, and will not be discussed in any great detail.
Against this background, the core choice model specification was developed in a sys-
tematic fashion, as follows.
1. We undertook preliminary work to ensure that the data met appropriate quality
standards.
2. We initially developed separate models for each mode and SP game (i.e. SP1-3).
3. Having identified the set of covariates applicable to each mode and game, we jointly
modelled SP1-3 for each mode.
4. Developing the models further, we introduced additional elements of functionality
(described in the following sub-sections), and identified the final specification to be
taken forward to the Implementation Tool used for generating appraisal values in
fourth section.
The field of choice modelling has evolved substantially since the 2003 national VTT
study in the UK (Mackie et al. 2003). The present study exploited many of these devel-
opments, relating to the error structure of the models, the treatment of reference depen-
dence (size and sign effects) and the incorporation of unobserved preference heterogeneity
in valuations. These developments are summarised in the following sub-sections, but
interested readers may wish to refer to the fuller technical discussion in the final report of
the study (Arup, ITS Leeds and Accent 2015a; Chapter 4) or the companion journal paper
(Hess et al. 2017).
Multiplicative versus additive error structures
As is well-established, the utility in a choice model is decomposed into deterministic and
random components, where the latter is referred to as the ‘error’ term.
The 2003 national study employed standard additive error structures, used in most VTT
studies worldwide since the pioneering UK work (Daly and Zachary 1975), where
U ¼ V þ e, with V and e giving the deterministic and random components of utility,
respectively. In the present study, we diverged from this assumption by employing models
based upon a multiplicative formulation (Harris and Tanner 1974; Fosgerau and Bierlaire
2009). In a multiplicative formulation, we replace the typical additive specification of the
utility of an alternative U ¼ V þ e by U ¼ V � e, where V and e are still defined as the
deterministic and random components of utility, respectively. That is, the random (error)
Transportation
123
component of utility is taken to multiply the deterministic component, rather than be added
to it.
The multiplicative formulation represents the state-of-the-art in VTT estimation for
experiments of the SP1 type, and its advantages were further verified in tests conducted for
the present study; again see the final report for further details (Arup, ITS Leeds and Accent
2015a; Section 4.4). A corresponding approach for SP2 and SP3 is also possible, and was
used here, in common with the most recent Danish national VTT study (Fosgerau et al.
2007), but with additional development to accommodate reference dependence.
The practical advantage given by the multiplicative approach is that it becomes much
easier to make an assumption of constant variance for e. In general, it is found that utility
variance increases as utility increases and this is handled automatically in the multi-
plicative form of the model. This benefit is confirmed by the improved model fit given by
multiplicative models in this context.
In the multiplicative model, it is practical9 to work with log U ¼ log V þ log e, the log
function having no impact on the ranking of utilities, since it is a monotonic transfor-
mation. Technically, the assumptions regarding the distributions of e are different in these
cases. In practice, it is assumed that e follows a log-extreme value distribution in the
multiplicative model, so that the simple logit model can be used to calculate probabilities.
Size and sign effects
Many SP-based VTT studies, including the 2003 study, have found that the values obtained
depend on the sign and size of time and cost changes relative to a ‘reference’ value. These
findings can be related to Prospect Theory, e.g. that gains are attributed a lower absolute
value than equivalent losses (Kahneman and Tversky 1979). When travellers are inter-
viewed relative to a specific trip, the reference value for a given attribute is often and
reasonably taken to be the corresponding value on that trip.
The present study tested reference-dependent effects for all SP models, but not for the
RP models, since in the latter case it was unclear what constituted the reference value.
Similarly, reference-dependent effects could not be included for those attributes in the SP
survey where no immediate reference values were available, such as reliability, or where
the number of possible effects due to reference dependence were too large to test efficiently
and too difficult to implement in model application, such as crowding. In particular, we
adopted the principles of de Borger and Fosgerau’s (DBF’s) (2008) approach to modelling
reference dependence—which is arguably the most sophisticated practical approach to
date—and further developed it for present purposes.
In essence, this approach specifies a value function v(.) between the ‘target’ and ‘ref-
erence’ trips. Along the lines of equation (5) in DBF we used S Dxð Þ ¼ Dx= Dxj jð Þ and Dx as
measures of sign and size inside the value function respectively, where Dx ¼ x � x0
captures the size difference from the reference trip. Illustrating for SP1, the implication of
this specification is that respondents value the SP cost differences by v Dc1ð Þ � v Dc2ð Þð Þand time differences by v hDt1ð Þ � v hDt2ð Þð Þ, where v denotes the value of a time change
from the reference and h is the ‘underlying’ VTT. It is then ‘rational’ to choose the slower/
cheaper alternative if v Dc1ð Þ � v Dc2ð Þj j[ v hDt1ð Þ � v hDt2ð Þj j. Estimation of DBF’s value
function identifies three parameters, representing: (a) differences in gain value and loss
value from the ‘underlying’ value; (b) non-linearity in the impacts of gains and losses;
(c) differences in the non-linearity of value for gains and losses. The key methodological
9 It is not difficult in practice to arrange that V [ 0 and e[ 0.
Transportation
123
development here was to extend the DBF approach to attributes other than time and cost,
thereby accommodating SP2 and SP3; fuller discussion of this can be found in the final
report (Arup, ITS Leeds and Accent 2015a, Section 4.6.2).
Joint modelling of SP1-3
Whilst initial tests were conducted separately on the individual SP games (mentioned
above when comparing the additive and multiplicative specifications), the majority of our
work made use of models jointly estimated on multiple games. This was in line with our
decision to present each respondent with three games of five choice tasks each. The main
benefit of joint estimation was increased robustness for those parameters shared across
games, which in the present case encompassed the set of covariates explaining deter-
ministic heterogeneity in valuations, as well as the random heterogeneity parameters.
In the joint estimation, we allowed for differences in valuations across games by using
separate multipliers for each valuation in our models (across the three games), relating it to
a base VTT. This allowed us to capture differences in valuations that clearly related to
different components (e.g. reliability as opposed to travel time), but also to test for dif-
ferences in interpretation for attributes common to different games, such as generic travel
time in SP1 and SP2.
Deterministic variation in modelled values
Another area of interest is the extent to which estimates of VTT are influenced by features
of the traveller and/or trip—such as the traveller’s income or the length of the trip. We
conducted an extensive search for factors causing variation in the values, involving a large
number of traveller/trip features collected in the course of the RP and SP surveys.
As has consistently been found in other national studies, we found significant evidence
of VTT increasing with income. This relationship was found in all mode/purpose segments
except for bus and ‘other PT’ commuting. We also found that VTT varied with the travel
time and cost of the trip. Given that both of these factors are closely related to distance, the
implication of these results was that VTT increased with trip distance.
Having tested the influence of a wide range of factors on VTT, it is interesting to note
that, all else equal, time use (i.e. the traveller’s ability to do something else whilst trav-
elling, to work or surf the net), geography (i.e. area, urban/rural), current travel conditions
(i.e. congestion and crowding) and current road types had little or no impact on VTT. This
could be an indication that travellers, when completing hypothetical choice tasks, do not
necessarily relate these back to the real world journey which these choice tasks relate to.
The result relating to time use is of particular interest, and it is perhaps useful to digress
slightly and provide additional background concerning the survey approach in this regard.
Focussing here upon employees’ business travel, since this represents a key segment
potentially affected by the productivity of travel time, respondents were reminded of their
reported one-way trip time and asked approximately how much of that time was spent
undertaking work and non-work related activities.
With reference to Fig. 6, the main activities undertaken by mode were:
• Car listening to music (53 min on average) and driving (17 min).
• Train using smart phone/eBook/tablet/computer (33 min, of which 17 min was work
related), work related use of laptop/tablet (26 min), doing nothing/relaxing/looking out
Transportation
123
of window (22 min), listening to music (14 min) and other work related to employment
(13 min).
The 2009 report on ‘Productive use of rail travel time and the valuation of travel time
savings for rail business travellers’ (Mott MacDonald et al. 2009) used slightly different
categories, and showed the proportion of travellers undertaking work-related activities as
follows: preparing for a meeting (38%), making/receiving calls (43%), talking to col-
leagues/other (12%), use of a laptop (23%), use of a PDA/Blackberry (25%), other work
related to employment (36%).
By comparison, in our own SP survey, 35% used a laptop, 56% used a Smartphone/
Blackberry and 29% did other work related to employment. There has been a notable in-
crease in the use of electronic devices for work-related activities on-train since 2009.
Nonetheless, it is clear that a large proportion of rail travel time is spent on non-work
activities.
One of the main criticisms of the Department’s CSA-based values for business travel
was that they failed to reflect the increasing opportunities for people to work whilst
travelling. However, an attraction of WTP is that valuations should in principle reflect how
travel time is used, given current travel conditions and opportunities to use that time.
Whilst our results indicated that VTT did not vary with time use, this is not to say that time
use is unimportant. It is possible that the results could have been different if the oppor-
tunities to use travel time productively had been substantively different for the trips being
made when surveyed. Another possibility is that, despite our best efforts, the importance of
time use was not fully captured by the SP exercises employed.
Returning to our more general interest in deterministic variation of VTT, we found
evidence of size and sign effects, although these varied in their nature and strength across
modes, games and attributes (i.e. time and cost). It is conceivable that such effects were an
artefact of the SP exercises, but even if they were not, a given reference point could
Fig. 6 Activities undertaken by employees during trip (average minutes) by mode
Transportation
123
become less relevant as travellers and travel conditions change over time. Notwithstanding
such considerations, we ideally require ‘reference free’ estimates of VTT for appraisal
purposes. To this end, the modelling work sought to identify the prevalence of size and
sign effects, before eliciting VTTs which ‘neutralised’ these effects.
For the majority of the aforementioned sources of variation, multipliers of the VTT
were estimated, with one category of a given attribute being used as the base—in which
case the multiplier was set to a value of one. This means that the base estimate of the VTT
related to an individual and trip at the base values for these covariates. We will return to
this point in the discussion of the actual model results (see the ‘‘Appraisal values’’ section
to follow).
Finally, it is worth mentioning that we tested for any significant differences in valua-
tions between online and CATI sub-samples. While this revealed statistically significant
differences in model scale between the two samples, the VTT differences were not sig-
nificant at usual levels of confidence.
Random taste heterogeneity
In accordance with current best practice, the final area of model development involved
allowing for random heterogeneity in the VTT. For the present study, after testing popular
alternatives such as the log-normal distribution, we settled on the log-uniform distribution.
This has a somewhat shorter tail than the log-normal, and any differences in fit were found
to be very small, with the log-uniform avoiding problems with extreme values. Unlike
some recent national VTT studies (e.g. Borjesson et al. 2012), the log-uniform also avoided
the need for censoring of the tails (see the discussion in Hess et al. 2017).
Appraisal values
The models described in the ‘‘Choice modelling’’ section, which supply the formulae for
VTT as a function of covariates, were estimated on an unrepresentative sample of trav-
ellers. Whilst we would not expect this to bias the coefficients, the models cannot, without
further information, provide appropriate values for selected aggregations of the travelling
population, as would be required for establishing recommended values for appraisal.
In the 2003 study (Mackie et al. 2003), the only covariates were distance10 and income,
whilst separate models were derived for the commuting and other non-work purposes
(given the adherence to the CSA, the business models were not taken forward to guidance).
This meant that representative values could be calculated by providing a representative
matrix of trips for each ‘cell’ representing a combination of distance and income, applying
the formula to each cell, and calculating a weighted average. In the present study, by
contrast, the scope of the model was much wider in that (a) it contained many more
covariates and (b) valuations were generated for a number of quantities in addition to travel
‘time’, such that a matrix-based approach would have been unwieldy.
10 In fact, trip distance was not collected in the 1994 data, so that the variable appearing under this name is aconstruct derived from the reported cost (the 1994/2003 study covered car travel only).
Transportation
123
Sample enumeration approach
Whilst the principles are essentially the same, it was more convenient to make use of a
‘sample enumeration’ approach. This involved the calculation of appropriate valuations (of
time, etc.) for each observation in the sample, making use of the relevant covariates,
followed by the calculation of weighted averages over the sample to ensure national
representativeness. We can represent this mathematically as follows:
�v ¼P
n wnv znð ÞP
n wn
where �v is the weighted average, n represents an observation in the sample with wn the
necessary weighting to obtain representativeness, v(.) is the time value formula derived
from the model as a function of a vector of covariates z, and zn is the set of covariates
relating to observation n.
As the best way of ensuring national representativeness, it was agreed with the
Department that we would use the NTS sample of trips made by persons over 16 years of
age by all motorised modes collected during the years 2010–2012. It was judged that a
three-year period was appropriate for giving a representative picture of current (as opposed
to historical) travel behaviour, and 2012 was the most recent year at our disposal.11 At the
time of undertaking this work, a further update of NTS to 2013 was pending, but it was not
anticipated that this update would introduce significant differences. While NTS is—in
common with the RP and SP datasets—a sample, it contains a set of weights aimed at
achieving a representative picture of national travel.
For each trip in the NTS sample, the recommended choice model arising from the
‘‘Choice Modelling’’ section was used to calculate appropriate valuations, taking account
of the covariates of the NTS record. This calculation made use of the same ‘code’ used in
the model estimation procedure, to ensure complete compatibility. In addition, the esti-
mated standard errors (etc.) were transferred, such that each NTS trip generated infor-
mation about the statistical reliability of its valuations, obviating the need for a special
subsequent step to calculate the confidence intervals associated with the recommended
values.
Note that it is possible to restrict the calculation of the quantity to summations over the
NTS sample observations with particular characteristics, whether or not these character-
istics are within the set of covariates defining the valuation formula. In this way, it is
possible to derive separate valuations for e.g. geographical breakdowns or for income
bands, as well as mode, purpose etc. In order to provide maximum flexibility for the
Department, an ‘Implementation Tool’ was developed in ‘R’, which permits the calcula-
tion of valuations for different segments and based on a variety of weighting options.
Conceptual issues
Aside from the above considerations, the translation of behavioural values of travel time,
reliability and associated quality factors into values suitable for use in appraisal provokes a
number of technical considerations; the following sections will highlight the principal such
considerations.
11 The NTS data available in the ‘special licence version’ has been used.
Transportation
123
Trip versus distance weighting
Invariably, practical demand modelling does not occur at a level of disaggregation con-
sistent with the covariates used in the choice models, because of constraints in the data
underlying the demand model. This has implications for appraisal, since it creates a need
for some form of average VTT and—following from the discussion in the ‘‘Sample enu-
meration approach’’ section—a need to re-weight this average for representativeness.
The two principal candidates for re-weighting are trip rates and distance travelled. The
previous WebTAG values were distance-weighted averages. There are two arguments in
support of this position. Firstly, the probability that a trip will experience a travel time
change is a function of trip distance. When transport interventions are targeted on specific
links in the network, long trips have more chance of experiencing a travel time
improvement than short trips—as they travel over more ‘links’.12 Secondly, at a more
conceptual level it was argued in Section 7.3 of Mackie et al. (2003) that if individuals j
have different values of time vj and travel time tj, it would seem sensible to try to ensure
that �vP
j
tj ¼P
j
tjvj, such that the value of the total time disutility is correct. Since time is
reasonably correlated with distance, a distance weighting would be one way of achieving
this—although the presence of congestion can reduce the degree of correlation.
Income effects
Another technical consideration is whether the VTT used in appraisal should be a pure
WTP value or should be adjusted to a standard value reflecting the income distribution of
the travelling population. Discussions with the Department identified essentially four
possible ways of dealing with this issue:
Option (1): Averaging over income, but not segmenting by income This was the
Department’s approach in previous WebTAG guidance, where the effect of income is
included when calculating the value for each trip VTT. These VTTs are then averaged to
give single, ‘standard’ values for commuting and other non-work (and other levels of
segmentation).
Option (2): Calculating values at ‘average’ income This approach is similar to option
(1) but treats all trips in the weighting process as having ‘average’ income. The user
specifies household income (for non-work VTT) and personal income (for business VTT).
Option (3): Removing the income covariate from the choice model, thus allowing the
effect to be picked up by other covariates This is a pragmatic option, but introduces model
misspecification.
Option (4): Applying distributional weights from the ‘Green Book’13 Values are again
calculated for each trip, using the same parameter values as under option (1). The resulting
values are then weighted, according to the income quintile which the income band falls in,
using the weights given in the Green Book (HM Treasury 2013). This would apply to non-
work trips only.
12 Notwithstanding the theoretical argument for distance-weighting, we drew reassurance from theempirical finding that, on segmenting VTT by distance, we found little difference between distance- andtrip-weighted VTTs across modes and purposes. For further discussion, see Section 7.6 of the study report(Arup, ITS Leeds and Accent 2015a).13 The Green Book details the HM Treasury’s ‘‘guidance for public sector bodies on how to appraiseproposals before committing funds to a policy, programme or project’’.
Transportation
123
Size effects
The modelling analysis in third section indicated the clear presence of ‘design’ effects in the
SP data. The specific modelling approach used (based on DBF) meant that sign effects
cancelled out in the VTT calculations, but the same did not apply to size effects. In other
words, the VTT calculations were dependent upon the size of the time change from the
reference (denoted Dt). Therefore, in translating these behavioural values to appraisal val-
ues, it was necessary to make a definitive assumption concerning Dt. Informed by analysis of
the sensitivity of VTT to different Dt, together with review of the corresponding assump-
tions employed in the most recent Danish (Fosgearu et al. 2007) and Swedish (Borjesson and
Eliasson 2014) national studies, we eventually settled upon a Dt of 10 minutes.
Mode-specific values
Mackie et al. (2003) in Sections 7.3 and 8.3 noted a number of reasons why values might
vary by mode:
(1) The income and socio-economic characteristics of travellers might vary systemat-
ically by mode. Low income users with low average VTT might gravitate to mode A
while high income users with high average VTT might tend to choose mode B.
(2) The composition of trips and purposes might vary systematically by mode. Mode A
might have a strong market share in short distance trips, while mode B might be
stronger at longer distances.14
(3) A cross-section of people with given income and socio characteristics making a
given trip will have a distribution of values of time (and individual values may vary
according to the constraints faced). People with low VTT for that trip will self-select
into relatively low cost/high time modes and vice versa.
(4) For any individual, VTT by mode may vary due to the different characteristics of the
modes in terms of comfort, cleanliness, reliability, level of personal control, and
other quality attributes.
Mackie et al. argued that, point (4) aside, individuals should, from a theoretical per-
spective, have the same VTT for a given trip regardless of mode used, hence favouring an
approach which picks up (1) to (3) through the income, socio-economic characteristics and
trip and purpose characteristics of the traffic modelled to the various sub-markets. Any
remaining variation in VTT should then reflect ‘comfort’ effects (note that these effects
could conceivably be related to ‘time use’, i.e. the extent to which travel time is used
productively or otherwise enjoyably, as discussed in the ‘‘Deterministic variation in
modelled values’’ section above).
In the present study we found that, even with income option (2)—where the effect of
income was neutralised—substantial differences by mode remained. The variation in VTT
by mode and person for a ‘typical’ person/trip combination is given in Table 7.
If the modal variation related solely to ‘comfort’, then we would expect the lowest
values for rail and the highest for bus, with car and ‘other PT’ intermediate. For com-
muting, we can see such an effect for car, rail and ‘other PT’, but the bus values are low
rather than high. For business, where bus is not of relevance, there does appear to be some
relation to comfort (especially in terms of the possibility of working on the train). For other
non-work, bus values are much higher, in line with the ‘comfort’ hypothesis, but the values
14 Given the much lower distance elasticities being found in the current study, this example has less force.
Transportation
123
for rail and ‘other PT’ go in the opposite direction to what we would expect. All in all, we
considered that these differences between modes could not be explained solely by comfort.
Given the above considerations and evidence, and in line with the argument in Mackie
et al., our preference for non-work was to retain mode-free values, by averaging the values
over the sample of trips for all (motorised) modes, maintaining the distance weighting.
Implementing this, but also maintaining (in the short term, at least) the approach of using
the SP1 values, the values given in Table 8 were obtained.
It can be seen that the two income options do not produce very different results, but
option (2) narrows the gap between commute and other non-work values. As might be
expected, the car values dominate, given that well over 80% of distance travelled is by car.
Reconciling different sources of evidence on business values
Much of the background thinking to the recommended approach to valuing business travel
time savings was undertaken in the scoping study which preceded the present study (ITS
Leeds, John Bates and KTH 2013), and what is reported here is essentially the imple-
mentation of that thinking. However, relative to the analysis of non-work trip purposes
where people are making their own travel decisions involving their own time and money,
business trip-making is inherently more complex and models require a greater degree of
interpretation and judgement. Whilst interested readers may wish to refer to the detailed
discussion in the report of the scoping study, it is perhaps useful to briefly summarise the
conclusions of that study, before reporting the new analysis which has been undertaken
here.
In the scoping study, we expressed reservations regarding the CSA traditionally
employed by the Department, essentially reiterating long-standing and well-rehearsed
concerns that not all travel time is unproductive and not all time savings would be con-
verted into productive use to the benefit of the company. In particular, the digital
Table 7 Ratio of modal VTT by trip purpose for an average person based on income option (2)(car = base)
Commute Other non-work Employees’ business
Car 1.00 1.00 1.00
Bus 0.51 2.14 N/A
‘Other PT’ 0.99 3.19 0.69
Rail 0.73 2.29 0.39
Table 8 All mode non-work VTT by treatment of income option (£/hr, perceived prices)
Commute Other non-work
Using income option (1) 11.21 5.12
Using income option (2) 10.03 5.49
Fixed income trip-weighted (option 2) is £49,684 for household (non-work) income. For personal income(EB) it is £35,070 for Car, £20,219 for Bus, £45,019 for ‘Other PT’, £55,319 for Rail. Ratio of distance-weighted VTT. Modelling used imputation for zero reported PT costs and employers paying for EB trips.Dt = 10. Tool version 1.1
Transportation
123
revolution has increased the potential for using travel time productively, and indeed can be
expected to have increased the productivity of any such time spent working while trav-
elling. Other arguments against the CSA surround difficulties in estimating the value of the
marginal productivity of labour (which underpins the approach), the benefits of spending
more time at the destination (say with a client or at a sales pitch), and the benefits of
avoiding overnight accommodation and travel in unsocial hours. By contrast, these effects
should in principle work themselves through into a WTP-based valuation, thereby eliciting
a reliable representation of what the company would pay.
We felt that an intuitively appealing approach would be to survey employers about how
much they would be prepared to pay to reduce their employees’ travel time. From a
conceptual point of view, it might be argued that employers should be the focus, since it is
they who will actually be purchasing the time savings. After all, if the CSA is a valid
representation of the value of business travel time savings, then the employer should
simply express a WTP in line with the CSA. Nonetheless, the difficulties of, and uncer-
tainties surrounding, a valuation approach based on surveying employers were recognised.
For example, the data collection costs are high, there are challenges involved in identifying
the appropriate employer agent, and even then the agent may not be entirely familiar with
specific kinds of business trips. Furthermore, another challenge is to achieve a represen-
tative sample of travel-using employers.
A potentially complementary approach is to undertake employee surveys, using either
RP or SP approaches, which are couched within an awareness of company travel policy.
Compared to collecting employers’ surveys, obtaining large samples of employees trav-
elling on company business is relatively straightforward, and indeed the business scoping
study demonstrated that SP studies along these lines tend to be the norm. The concern here
is whether employees are able to make choices in response to hypothetical scenarios that
accurately represent the company’s willingness-to-pay, or worse still simply represent their
own willingness-to-pay. If the employee is to be an acceptable proxy for the employer,
then we need employees to respond in accordance with the company’s interests as opposed
to their own private interests. An interesting special case here is self-employed business
travellers, where it might be presumed that company and private interests are one-and-the-
same, and that SP responses would therefore reflect what the company would pay.
In the scoping study, we expressed a preference for WTP-based approaches, using
different methods for corroborative and interpretive reasons. This reflected a proposition
that well designed and conducted quantitative research can provide a coherent ‘story’ as to
how business travel time savings are valued, or better still, can elicit direct estimates of
WTP that lend themselves to comparison against the CSA.
Against this background, the business travel component of the present study was
informed by three sources of survey evidence, namely employer SP, employee SP, and
employee RP. The information collected on income and working hours in the course of the
survey also allowed comparison with the CSA. In order to reconcile these different per-
spectives on business VTT, we pursued two lines of enquiry. First, we were interested in
the degree of similarity between SP-based estimates of VTT and the CSA (the RP-based
estimates were largely used as a corroborative device and will not be discussed in any
detail here). Second, we were interested in the degree of consistency between various
properties of the VTTs emanating from the different surveys.
Generally speaking, we found similar values for the two different SP analyses (em-
ployer and employee), and for some occupational types we also observed similar values for
the SP analyses and the CSA. This was particularly so for blue collar workers, who would
be expected to have relatively low productivity whilst travelling. For briefcase travellers,
Transportation
123
who are more likely to be productive, SP-based values appeared to be lower than the CSA.
Moreover, the degree of similarity between the SP-based VTTs and the CSA was partly
dictated by the trip length distribution, and did not hold over all distances. The self-
employed values were lower than those for employees; whilst we cannot substantiate
empirically, this result would seem plausible if the time saved is taken as leisure.
Turning to the properties of the VTT estimates, the theoretically-driven CSA embodies
an income elasticity of one (i.e. implying that VTT increases in direct proportion to
income) and applies a constant unit value to all trips (e.g. irrespective of time, cost,
distance, travel conditions, productivity, etc.). By contrast, the SP-based VTTs exhibited
income elasticities within the range 0.3–0.4 (and significantly less than one), and signifi-
cant variability by several of the aforementioned dimensions (and notably by distance).
Thus, whilst there was some correspondence between the actual estimates of VTT from the
CSA and SP analyses, this correspondence did not extend to key properties of those
estimates.
Having reconciled the various sources of evidence on business VTT through the lines of
enquiry summarised above, it was decided that the employee SP survey should be the
definitive source of evidence taken forward to the Implementation Tool. This was because
it generated—with some qualifications—similar values to the employer SP survey, but
offered a considerably more substantial dataset, amenable to generating statistically robust
values for a range of trip and traveller segments. Furthermore, the employee dataset was
more comparable to the NTS data used as the basis for the sample enumeration. That is to
say, the Tool applied the choice model from the employee SP to business trips in the NTS,
to derive an average value over specified segmentations, as shown in Table 9.
The average distance-weighted personal income across the NTS sample was £46,615
(2014 prices and values). This gives a business VTT in 2014 perceived prices of £28.27
using the CSA (second row, third column). This compares to the CSA-based WebTAG
values which have an all modes value of £25.47 (first row, third column). If we also
compare these values to the SP-based values re-weighted for NTS (third row), then we see
that the VTT for employees’ business across all modes is £18.23. This is 72% of the
WebTAG value. We also find substantial variation by mode with ‘other PT’ lowest at
£8.33 and rail highest at £27.61 for the all distance values. As proportions of the WebTAG
values, these range from 34% (‘other PT’) to 92% (rail).
We have already noted that the SP-based VTTs for business are sensitive to trip dis-
tance. From Table 9 we can also see that at low distances the SP-based values are sub-
stantially less than the previous WebTAG values, but as trip distances increase the SP-
based values increase to be close to the previous WebTAG values at long distances ([50
miles).
Reconciling different values of travel time savings from different SP games
The results from the simplest time/cost trade-off (SP1)—which is, of course, the game
most comparable to the results on which previous WebTAG guidance, using the 1994
AHCG data, was based—gave car values of £11.70 for commute, £4.91 for other non-
work, and £16.74 for employees’ business. For all purposes, the values fell between the
corresponding values from SP3 for light and heavy traffic, and this was in line with the
underlying model, since the relativities were unaffected by NTS re-weighting.
We had to form a judgment as to whether the SP1 and SP3 values were compatible, and
if not, which values to carry forward to appraisal. To do this, we reflected on how the time
values were presented in the SP tasks. For SP1, the instructions were:
Transportation
123
‘‘Please imagine that each situation is exactly the same as for #LEG2# actual car
journey at the time you made the journey, except… The one way travel time may be
different because of changes in congestion’’. Variations in cost were suggested in terms of
changed fuel cost.
It is noteworthy that in the 1994 survey (which was for car only) the corresponding
instructions were:
‘‘Please imagine that each situation is exactly the same as for your actual journey at the
time you were surveyed except… the travel time… can be different from the actual situ-
ation at that time because there is, for example, more or less congestion’’. Variations in
cost were suggested in terms of changes in petrol price or parking charges.
Hence in terms of the background to the SP1 experiment, it seemed fair to conclude that
they were identical in both surveys, with a clear suggestion to relate the changes to the
conditions of the reference trip. Any changes in results could therefore be attributed to:
(a) Changes in the SP design (this should largely improve the accuracy rather than lead
to different results per se).
(b) Changes in preferences and behaviour etc. (including the underlying NTS travel
characteristics).
(c) Changes in the method of analysis (in particular the switch from additive to
multiplicative model specifications with flexible heterogeneity patterns).
Respondents had previously been asked ‘about how much’ of their time was spent in
each of the three following conditions, presented in words and pictures, as:
‘‘Heavy traffic: Your speed is noticeably restricted and frequent gear changes are
required’’.
‘‘Light traffic: You can travel close to the speed limit most of the time, but you have to
slow down every so often’’.
‘‘Free-flowing: You can travel at your own speed with no problems over-taking’’.
Table 9 Business VTT by method of calculation, mode and distance (2014 perceived prices and values, £/hr)
Source/method Distance Allmodes
Car Bus ‘OtherPT’
Rail
Previous WebTAG (2014 prices and values) All distances 25.47 24.43 15.64 24.72 30.07
CSA estimate from NTS 2010–2012 data (2014prices and values)
All distances 28.27 27.05 13.13 26.33 36.46
Employees’ business SP re-weighted to NTS2010–2012 (2014 prices and values)
All distances 18.23 16.74 N/A 8.33 27.61
\5 miles 5.39 5.27 N/A 8.33 N/A
5–20 miles 8.84 8.79 N/A 8.28 10.19
[=20 miles 21.14 19.51 N/A N/A 28.99
[=50 miles 24.55 22.53 N/A N/A 32.56
[= 100miles
28.62 25.74 N/A N/A N/A
All modes. Distance-weighted, income option 1, SP1 Dt = 10; Tool version 1.1. PT cost is imputed for atrip with a zero cost, and employers paying for EB trips. WebTAG ‘Other PT’ is Underground passenger,WebTAG car EB is weighted average of driver and passenger (vehicle occupancy of 1.2)
Transportation
123
Attempts were made to relate the valuations from SP1 to these implied proportions of
congestion on their real life trip. However, the effects were generally weak,15 suggesting
that respondents related the valuations in SP1 not to their actual trip but to some imagined
congestion level, perhaps based on the changes in travel time from their current time.
Turning to the results from SP3, while these choice scenarios were again framed in
relation to the reference trip, the hypothetical journey times were now explicitly split into
different levels of congestion, and major differences were retrieved in how respondents
reacted to these. The SP3 values of time for commuters displayed ratios relative to free-
flow time (ff) of 1.4 for light traffic (lc) and 2.66 for heavy traffic (hc). For business the
ratios were 1.61 and 2.99, and for other non-work they were 1.76 and 3.98.
As already noted, NTS does not carry information on conditions for individual trips.
The Tool was therefore set up to calculate an average of the three types of time in SP3,
using the average shares in the SP sample for different purposes, as shown in Table 10.
Using these overall proportions, we obtained SP3-based values of £9.98 for commute,
£12.44 for business and £4.62 for other non-work. These are lower than the SP1-based
values reported at the beginning of this section: the commute value is 15% lower, the
business value 26% lower and the other non-work value 6% lower. It is arguable as to
whether this comparison is appropriate: the proportions are likely to be related to the kind
of trip (urban vs. inter-urban etc.), and the SP sample was certainly not representative in
terms of distance travelled. Nevertheless, it is also important to acknowledge that a game
of the SP1 type may overstate the value of time as respondents need to trade between only
one time and one cost component. As far as the implied variation in valuations for the three
levels is concerned, the levels presented are three possible positions within a continuum
related to the ‘volume/capacity’ ratio, and could be difficult to apply in practice, since they
would need to be aligned with actual traffic conditions in relation to volume-delay
functions.
On balance, we recommend that the Department should adopt the SP1 values in the
short term, but conduct further work to build confidence in the SP3 values and explore their
practical applicability in appraisal. Indeed, some progress towards these ends has already
been achieved, with Hess et al. (2017) demonstrating the greater robustness of SP3—
relative to SP1—towards reference dependence in the SP games. The future availability of
data on differing levels of congestion may permit the use of SP3 results in the medium
term, though there would still be the need to resolve how model output (in terms of
volume/capacity ratios) relates to the levels of congestion presented in the SP, and how to
interpolate between the free-flow, light and heavy traffic points.
Table 10 Average shares of congested driving conditions in the SP sample
Commute Other non-work Employees’ business
Free-flow 0.33 0.36 0.34
Light traffic 0.36 0.41 0.40
Heavy traffic 0.31 0.23 0.26
15 The multipliers (relative to free-flow) were reported for commuting as 1.40 for light traffic and 1.56 forheavy traffic: however, neither of these were significantly different from 1 at the 95% level. The corre-sponding values for other non-work were 1.36 and 1.46, again with neither being significantly different from1.
Transportation
123
VTT values for use in appraisal
Bringing the discussions presented in this section together, we can draw out some rec-
ommendations regarding the basis for VTTs for use in appraisal:
• Whilst each of the three SP games (i.e. SP1–3) could potentially be used to elicit the
‘headline’ estimate of VTT, we recommend that in the short term this should be based
on SP1 with Dt = 10. In the medium term, pending further development, there could be
a case for replacing SP1 with SP3.
• There are material differences between the three trip purposes, and we should therefore
continue to disaggregate VTT by trip purpose.
• VTT should continue to be distance-weighted, but should be disaggregated into
distance bands to reduce the level of approximation between the standard VTT values
and the ‘real’ scheme level VTT value. Further work is required to determine
appropriate distance bands for use in appraisal16,17.
• For non-work, we should use an ‘all modes’ value due to the non-work VTTs reflecting
some self-selectivity between modes. For business, we should use modal values as we
interpret differences between modes to represent real differences.
• In the case of business, the choice model in the sample enumeration should be based on
those employees who reported that their employers would be willing to pay for time
savings.
• We should distinguish between appraisals of small and medium sized schemes (referred
to as ‘Level 1’ in the UK), and appraisals of major schemes and policies (‘Level 2’) and
significant ‘user pays’ initiatives (‘Level 3’). For Level 1 appraisal, standard ‘national’
values of time can be used. For Level 2, the values may be amended to more accurately
reflect local conditions. For Level 3, appraisal values derived from bespoke quality
surveys would be appropriate.
For Level 1 and 2 appraisals, we make the additional recommendations:
• Non-work: for Level 1 appraisals with VTTs distance-banded, as recommended above,
we should use income option (2)—that is, treating all non-work trips as having the
same average household income (if however, distance-banding is not implemented—at
least in the short term—then income option (1) should instead be used17). For Level 2
appraisals, we should use income option (1) applied at the appropriate regional level.
• Business: for Level 1, income option (1) should be applied using national data, whilst
for Level 2, income option (1) should be applied at the appropriate regional level.
We have illustrated these recommendations for a Level 1 appraisal in Table 11. This
table also presents, for the purposes of comparison, the previous WebTAG values con-
verted to a comparable base (2014 perceived prices).
16 Whilst it falls outside the scope of the present paper, it is worth noting that, in responding to consultationon our recommended values, the Department subsequently revised the three distance bands shown inTable 11 into four bands (0–50 miles, 50–100 miles, 100–200 miles, and 200? miles) and, in the case ofbusiness, fitted a continuous function to these four bands (DfT 2017).17 For non-work, the Department opted not to disaggregate by distance (DfT 2017).
Transportation
123
VTT multipliers for use in appraisal
In addition to the overall VTTs, we also make recommendations for adjustments to these
values for different types of time, and we present these as multipliers. In doing this, we
must take account of the different VTTs coming from the different games, as well as our
general approach of using SP1 values for the overall recommendations about VTT.
With reference to the SP2 results, we found higher valuations based on the average time
presented in the reliability experiment relative to the SP1 values, by a factor of 1.31 for
commute, 2.17 for other non-work, and 1.52 for employees’ business. Now it might be
argued that by implying the possibility of unreliability, there is some suggestion of
(greater) congestion. However, the questionnaire said that the situation was the same as the
reference trip, while the reasons for variation in overall travel time were attributed to
‘improvements in traffic control’, and the variation (unreliability) was attributed to
‘breakdowns, unplanned roadworks, or general traffic’. It is not obvious that this has to
imply that SP2 values exceed SP1 values, particularly not at the scale seen for other non-
work, where the value was well in excess of that for heavy traffic.
This also presented a problem for the ‘reliability ratio’, as we had to decide whether to
take the value of the standard deviation relative to the SP2 VTT or the SP1 VTT. The
former gave values of 0.33 (commuting), 0.42 (business) and 0.35 (other non-work): the
latter gave values of 0.43, 0.64 and 0.77 respectively. The former values are low by
‘received wisdom’ (though the evidence base for that is not especially strong), while at
least for other non-work, the SP1-based result is close to the previous WebTAG value of
0.8.
On balance, it seemed more reasonable to interpret these values relative to the SP2 time
multiplier, on the grounds of internal consistency within the SP2 experiment. So, for
example, the reliability ratio for car was taken from the ratio of the ‘Value of sd travel
time’ to the value of ‘Average travel time’ from SP2, and multiplied by the relevant SP1
VTT to get an absolute valuation of the standard deviation (Table 12). The same approach
was taken for the early and late multipliers. This is also in line with the way reliability
ratios were derived in other work (e.g. Black and Towriss 1993). However, this is not a
strongly-based recommendation, and we are still left with the conundrum of explaining the
high SP2 time multiplier. The fact that the SP2 VTTs are rather higher than those for SP1
Table 11 Appraisal VTTs for a Level 1 appraisal (routine appraisal of small and medium sized schemes)with illustrative distance bands (2014 perceived prices, £/hr)
Source Distance Commute Other non-work
Employees’ business
Allmodes
All modes Allmodes
Car Bus ‘OtherPT’
Rail
WebTAG All 7.62 6.77 25.47 24.43 15.64 24.72 30.07
Re-surveyedvalues
All 11.21 5.12 18.23 16.74 N/A 8.33 27.61
\20 miles 8.27 3.62 8.31 8.21 N/A 8.33 10.11
20 to 100miles
12.15 6.49 16.05 15.85 N/A 8.33 28.99
[=100 miles 12.15 9.27 28.62 25.74 N/A 8.33 28.99
Distance weighted, ‘all distance’ values based on income option 1, for distance-banded values non-workbased on income option 2 (household income = £49,684) and business on income option 1, VTT imputedfor PT trips with zero cost, SP1 VTTs, Dt = 10, employers paying for EB trips, Tool version 1.1
Transportation
123
in the case of car and rail does mean, of course, that the implied valuations of reliability
will be lower. Without a clear understanding of the reason for the difference between SP1
and SP2 VTTs, this must remain an arbitrary judgment.
Relative to reliability, the remaining multipliers may be considered of lesser impor-
tance, but it is worth noting some additional complications which arose in the case of
public transport crowding (SP3). For the public transport modes, we chose to align the
results with the level of crowding closest to the SP1 VTT: for bus and other public
transport this corresponds to the level ‘‘a few seats free but had to sit next to someone/could
not sit with people travelling with. Some standing’’ (Table 13),18 while for rail it corre-
sponds to a load factor of 100% (i.e. ‘‘all seats taken but no standing’’ (Table 14).
Turning to SP3 for car, we note that in all cases the SP1 VTT fell inside the range
between the light and heavy traffic values from SP3, though it is difficult to justify this
Table 12 VTT multipliers, with SP2 VTT taken as base
Mode Multiplier Commute Other non-work Employees’ business
Car Reliability ratio 0.33 0.35 0.42
Bus Value of early -2.69 -3.20 N/A
Value of late 2.88 2.52 N/A
‘Other PT’ Value of early -2.40 -2.98 -1.66
Value of late 1.75 2.24 1.95
Rail Value of early -1.77 -2.34 -1.55
Value of late 2.86 3.21 2.76
Table 13 VTT multipliers, with SP3 VTT for ‘A few seats free but had to sit next to someone/could not sitwith people travelling with some standing’ taken as base
Mode Multiplier Commute Othernon-work
Employees’business
Bus Plenty of seats free and did not have to sit next to anyone 0.85 0.83 N/A
A few seats free but had to sit next to someone/could notsit with people travelling with
0.89 0.84 N/A
A few seats free but had to sit next to someone/could notsit with people travelling with Some standing
1.00 1.00 N/A
No seats free—a few others standing 1.24 1.30 N/A
No seats free—densely packed 2.14 2.32 N/A
‘OtherPT’
Plenty of seats free and did not have to sit next to anyone 0.95 1.00 1.00
A few seats free but had to sit next to someone/could notsit with people travelling with
0.97 1.00 1.00
A few seats free but had to sit next to someone/could notsit with people travelling with some standing
1.00 1.00 1.00
No seats free—a few others standing 1.13 1.10 1.17
No seats free—densely packed 1.70 1.87 1.78
18 There are multiple rows of ones in some cases, since the relevant multipliers were not significantlydifferent from one.
Transportation
123
apart from perhaps the commuting case. Since in any case we consider these ratios to be
only indicative of the possible impact of congestion, we divided the SP3 values for the
three levels by the SP1 VTT to get the multipliers in Table 15.
Variance and uncertainty around the results
As noted in the study aims in the ‘‘Study aims, scope, and delivery’’ section, the Imple-
mentation Tool was developed in such a way that it outputs not only the mean VTT, but
also the standard error of the mean and confidence intervals. The latter takes account of
both estimation error and NTS sample error, where the latter is a development beyond
previous examinations of VTT uncertainty (Wheat and Batley 2015). Using this func-
tionality, 95% confidence intervals were calculated for income option (1) based on dis-
tance-weighting.
Whilst the multiplicative models gave direct estimates of WTP measures, the additive
models were estimated in preference space, hence giving estimates for the component
marginal utilities. These were then used to calculate WTP measures, by taking ratios
against the cost coefficients, and standard errors for the WTP measures were computed
using the Delta method to allow for errors in the estimated parameters. This is known to
give the exact same result as working in preference space, both for the estimates and the
standard errors, using MNL models (Daly et al. 2012a, b). Additionally, using the bootstrap
method, we calculated errors that allowed for the fact that the NTS is itself a sample.
Table 14 VTT multipliers, with ‘seated 100% load’ taken as base
Mode Multiplier Commute Other non-work Employees’ business
Rail Seated 50% load 0.73 0.72 0.75
Seated 75% load 0.79 0.72 0.76
Seated 100% load 1.00 1.00 1.00
Seated 1 pass per m2 1.09 1.14 1.13
Seated 3 pass per m2 1.31 1.39 1.36
Standing 0.5 pass per m2 1.16 1.21 1.29
Standing 1 pass per m2 1.19 1.27 1.38
Standing 2 pass per m2 1.32 1.57 1.56
Standing 3 pass per m2 1.57 1.79 1.61
Standing 4 pass per m2 1.86 2.17 2.03
Table 15 VTT multipliers, with SP1 VTT taken as base
Mode Multiplier Commute Other non-work Employees’ business
Car Free-flow 0.51 0.47 0.42
Light traffic 0.72 0.83 0.68
Heavy traffic 1.37 1.89 1.26
Bus Value of free-flow 0.99 1.22 N/A
Value of slow down 1.39 1.36 N/A
Value of dwell time 0.68 1.57 N/A
Value of headway 1.68 1.60 N/A
Transportation
123
Though we do not present the confidence intervals here—interested readers can find
them in the final report19 (Arup, ITS Leeds and Accent 2015a; Section 7.7)—we note that,
broadly speaking, the models and associated VTTs were well-estimated. In general, the
confidence intervals for the VTT from SP1 were just below ±30% of the mean; rail and
‘other PT’ had the narrowest confidence intervals, whilst bus had the widest intervals.
Another finding was that the SP1 VTTs had slightly narrower confidence intervals (\30%)
than SP2 and SP3. All of the valuations were found to be significantly different from zero,
apart from the value of bus dwell time.
Summary and conclusions
In summarising and concluding this paper, it is appropriate to draw reference to the four
aims introduced at the outset (see the ‘‘Study aims, scope, and delivery’’ section).
To provide recommended, up-to-date national average values of in-vehicle travel time
savings, covering business and non-work travel, and based on primary research using
modern, innovative methods.
Within the standard microeconomic framework of goods versus leisure trade-off subject
to money and time constraints, we employed Stated Preference (SP) experimental methods
to estimate WTP for time savings, for travellers in the course of business and non-work
trips. The SP involved three games, which considered different trade-offs, namely: SP1
(time vs. money), SP2 (time vs. money vs. reliability), and SP3 (time vs. money vs.
crowding/congestion).
The main field survey employed, primarily, an intercept-based recruitment approach at
around 30 representative locations across England for each mode. Recruits were directed to
a web-based questionnaire, and were paid a nominal reward on completion of the ques-
tionnaire. Potential gaps in this primary approach (e.g. infrequent travellers and/or those
without computer access) were covered by a secondary approach of telephone recruitment
and telephone and/or paper-based administration of the questionnaire. The field survey was
completed successfully; most targets were achieved, and overall the pilot survey provided a
good guide to the likely success, issues and response rates in the field survey.
To investigate the factors which cause variation in the values (e.g. by mode, purpose,
income, trip distance or duration, productive use of travel time etc.) and use this to inform
recommended segmentation of the values.
The modelling was developed in a systematic fashion, whereby alternative model
specifications were tested in relation to:
• time and cost gains, losses and size effects;
• person characteristics such as age, gender, employment status, household composition
and income; and
• trip characteristics such as mode, purpose, distance and geography.
All values were reported by purpose and mode—given the importance of these variables
as key policy segments—and as a function of income elasticity, as well as a function of
elasticities with respect to the time and cost of the ‘reference’ trip. Where other covariates
19 The final report also discusses the potential sources of variance, which in the present case include: (1)differences in the estimation errors in the behavioural models by mode and purpose; (2) differences in therepresentativeness of the NTS data by mode and purpose leading to different bootstrapping errors; and (3)differences in sample size.
Transportation
123
were identified as significant, these were retained in the preferred choice models and, in
turn, fed into the process of eliciting values for implementation in appraisal.
Indeed, a key task was the progression from the values derived from best specification
models to recommended values for use in appraisal. This entailed four steps:
• review and modification of the choice models in the light of interpretation;
• specification of standard values to be produced;
• re-weighting of those values for national representativeness using the National Travel
Survey (NTS); and
• assumptions concerning changes in VTT over time.
To assist the Department’s analysts in generating VTTs for appraisal guidance, we
developed an ‘Implementation Tool’ which calculates VTT for different segments, based
on a variety of weighting options. Rather than just apply weights from the NTS sample to
the respondents in our estimation data, we made use of sample enumeration which applies
the estimated models to the respondents in the NTS sample.
To improve our understanding of the uncertainties around the values, including esti-
mating confidence intervals around the recommended values.
For any appraisal scenario of interest to the user, the Implementation Tool generates
confidence intervals around the mean VTT. This estimation takes account of two potential
sources of uncertainty in values, namely:
• error in the mean VTT arising from the parameters estimated in the choice model; and
• error in the NTS sample, which arises from the fact that NTS is a sample drawn from
the travelling population.
More generally, we demonstrated the robustness of the estimated values through a
number of exercises. First, we validated our SP values against comparable RP values. This
exercise involved the design and implementation of separate SP and RP experiments
around a common choice context—namely the choice between competing rail operating
companies for medium distance rail trips to London. Whilst the resulting values were
somewhat high, due to confounding with operator preferences, the SP and RP delivered
similar results. Second, we validated our preferred choice model specification by testing
against alternative specifications, including the recommended model from the 2003
national study. This demonstrated the greater functionality and superior statistical fit of the
2015 model, as compared with the 2003 model. Finally, it should be noted that any
decisions in relation to model structure were not solely based on best practice from past
studies and more recent developments in the academic literature, but also on extensive
testing on the data at hand, such as tests comparing additive and multiplicative model
structures.
To consistently estimate values for other trip characteristics for which values are
derived from the values of in-vehicle time savings.
Whilst Stated Preference experiment 1 (SP1) offered the respondent trade-offs between
time and cost, SP2 and SP3 offered trade-offs between travel time, cost, reliability and
congestion/crowding. The objectives of this exercise were three-fold: first, to ascertain
whether, and to what extent, the ‘headline’ VTT from SP1 was confounded with the value
of reliability and congestion/crowding; second, to estimate incremental multipliers for
reliability and congestion/crowding suitable for implementation in appraisal; and third, to
gain insights into what the SP1 values represented in terms of type of time (i.e. trip
conditions).
Transportation
123
The use of the joint modelling framework across all games allowed us to examine the
differences between individual valuations across games. This joint estimation yielded key
insights, for example showing the extent of VTT increases with road congestion (for car
and bus), as well as with the level of crowding (for all PT modes). It also showed dif-
ferences across modes and across purposes as to what type of trip conditions in SP3 the
values from SP1 relate to. The values coming out of SP2 diverge from those of SP1 and
SP3, and this is likely to be a behavioural impact in terms of how respondents reacted to
variability in travel time.
Acknowledgements The authors acknowledge the constructive feedback from the anonymous peerreviewers, which significantly improved the content and composition of this paper. Furthermore, the authorsacknowledge the contributions of various parties which helped to facilitate the research study whichunderpins this paper, as follows. Staff from the UK Department for Transport’s ‘Transport Analysis andStrategic Modelling’ (TASM) Division, in particular the project officer Adam Spencer, and colleagues AliceCrossley, Margot Shatz and Marcus Spray, who guided the study on a day-to-day basis. Members of theDepartment’s wider Project Board, who reviewed the progress and direction of the study at key milestones.Stakeholders from various public and private sector organisations across the UK transport sector, whoattended workshops at the outset of the study and at the end of the survey design and testing phase.Operators of railway stations, ‘other PT’ services, motorway service stations, petrol stations and other areaswhere interviewers worked. Members of the Analytical Challenge Team who reviewed our Main Report andoffered comments namely Professor Glenn Lyons (University of West of England, UK), Professor JonasEliasson (Royal Institute of Technology, Sweden) and Professor Kay Axhausen (Swiss Federal Institute ofTechnology). Whilst the study was guided, monitored and reviewed by the Department, the results reported,findings inferred, and views expressed are the responsibility of the authors, and not necessarily a statementof the Department’s policy or guidance.
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 Inter-national License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution,and reproduction in any medium, provided you give appropriate credit to the original author(s) and thesource, provide a link to the Creative Commons license, and indicate if changes were made.
References
Accent and Hague Consulting Group (AHCG): The value of travel time on UK roads. Report to Departmentfor Transport (1999)
Arup, ITS Leeds, Accent: Provision of market research for value of time savings and reliability. Phase 2report to the Department for Transport (2015a). https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/470231/vtts-phase-2-report-issue-august-2015.pdf
Arup, ITS Leeds, Accent: Provision of market research for value of travel time savings and reliability. Walkand Cycle report to the Department for Transport (2015b). https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/470237/vtts-walk-and-cycle-report-issue-14-aug-2015.pdf
Association of Train Operating Companies (ATOC): Passenger Demand Forecasting Handbook. Associationof Train Operating Companies, London (2012)
Becker, G.: A theory of the allocation of time. Econ. J. 75(299), 493–517 (1965)Black, I.G., Towriss, J.G.: Demand Effects of Travel Time Reliability. Centre for Logistics and Trans-
portation, Cranfield Institute of Technology, Cranfield (1993)Borjesson, M., Fosgerau, M., Algers, S.: Catching the tail: empirical identification of the distribution of the
value of travel time. Transp. Res. Part A 46(2), 378–391 (2012)Borjesson, M., Eliasson, J.: Experiences from the Swedish Value of time study. Transp. Res. Part A 59,
144–158 (2014)Daly, A.: Cost damping in travel demand models. Report of a study for the Department for Transport (2010).
http://assets.dft.gov.uk/publications/pgr-economics-rdg-costdamping-pdf/costdamping.pdfDaly, A.J., Hess, S., de Jong, G.: Calculating errors for measures derived from choice modelling estimates.
Transp. Res. Part B 46(2), 333–341 (2012a)Daly, A.J., Hess, S., Train, K.E.: Assuring finite moments for willingness-to-pay in random coefficients
models. Transportation 39(1), 19–31 (2012b)
Transportation
123
Daly, A., Zachary, S.: Commuters’ values of time. Report to Department of the Environment, LGORUreport T55, January (1975). http://www.alogit.com/General_papers.htm
De Borger, B., Fosgerau, M.: The trade-off between money and travel time: a test of the theory of reference-dependent preferences. J. Urban Econ. 64(1), 101–115 (2008)
Department for Transport (DfT): Understanding and valuing the impacts of transport investment: latest DfTtechnical research and next steps in transport appraisal (2013). https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/253485/technical-research-next-steps-appraisal.pdf
Department for Transport (DfT): TAG unit A1.3: User and provider impacts, November (2014). https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/539338/webtag-tag-unit-a1-3-user-and-provider-impacts-november-2014.pdf
Department for Transport (DfT): Understanding and valuing impacts of transport investment: values oftravel time saving. Moving Britain ahead’ (2015). https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/470998/Understanding_and_Valuing_Impacts_of_Transport_Investment.pdf
Department for Transport (DfT): Understanding and valuing impacts of transport investment: value of traveltime saving consultation response. Moving Britain ahead (2016). https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/544165/understanding-and-valuing-the-impacts-of-transport-investment-values-of-travel-time-savings-consultation-response.pdf
Department for Transport (DfT): TAG unit A1.3: User and provider impacts, February (2017) (in press)De Serpa, A.: A theory of the economics of time. Econ. J. 81(324), 828–846 (1971)Evans, A.: On the theory of the valuation and allocation of time. Scott. J. Polit. Econ. 19(1), 1–17 (1972)Fosgerau, M., Hjorth, K., Lyk-Jensen, S.: The Danish Value of Time Study: Results for Experiment 1.
Danish Transport Research Institute (2007)Fosgerau, M., Bierlaire, M.: Discrete choice models with multiplicative error terms. Transp. Res. Part B
43(5), 494–505 (2009)Fowkes, T., Wardman, M.: The design of stated preference travel choice experiments. J. Transp. Econ.
Policy 22(1), 27–44 (1988)Harris, A.J., Tanner, J.C.: Transport demand models based on personal characteristics. Transport and Road
Research Laboratory Supplementary Report SR65UC, Crowthorne, UK (1974)Harrison, A.J.: The Economics of Transport Appraisal. Croom Helm, London (1974)Hensher, D.A.: Value of Business Travel Time. Pergamon Press, Oxford (1977)Hess, S., Daly, A., Dekker, T., Ojeda Cabral, M., Batley, R.: A framework for capturing heterogeneity,
heteroskedasticity, non-linearity, reference dependence and design artefacts in value of time research.Transp. Res. Part B 96, 126–149 (2017)
Treasury, H.M.: The Green Book: Appraisal and Evaluation in Central Government. Treasury Guidance,TSO, London (2013)
Hollander, Y.: Direct versus indirect models for the effects of unreliability. Transp. Res. Part A 40(9),699–711 (2006)
International Transport Forum: Valuing Convenience in Public Transport. Roundtable report 156. OECD,Paris, France (2015)
ITS Leeds: M6 Toll study: modelling of passenger choices. Final report to the Department for Transport(2008). https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/194011/passenger-surveys-report.pdf
ITS Leeds, John Bates, DTU: Updating appraisal values for travel time savings Phase 1 study. Report to theDepartment for Transport (2010). https://www.gov.uk/government/publications/values-of-travel-time-savings-updating-the-values-for-non-work-travel
ITS Leeds, John Bates, KTH: Valuation of travel time savings for business travellers. Main report, preparedfor the Department for Transport (2013). https://www.gov.uk/government/publications/values-of-travel-time-savings-for-business-travellers
Kahneman, D., Tversky, A.: Prospect theory: an analysis of decision under risk. Econometrica 47(2),263–291 (1979)
MVA, ITS, TSU: The Value of Travel Time Savings. Policy Journals, (1987)MVA: Valuation of overcrowding on rail services. Prepared for Department for Transport (2008)Mackie, P.J., Wardman, M.R., Fowkes, A.S., Whelan, G.A., Nellthorp, J., Bates, J.J.: Value of travel time
savings in the UK. Report to Department for Transport (2003). http://eprints.whiterose.ac.uk/2079/2/Value_of_travel_time_savings_in_the_UK_protected.pdf
Mott MacDonald, Hugh Gunn Associates, TRI Napier University, Accent and Mark Bradley Research,Consulting: Productive use of rail travel time and the valuation of travel time savings for rail businesstravellers. Final report to the Department for Transport (2009)
Transportation
123
Rose, J.M., Bliemer, M.C.J.: Survey artefacts in stated choice experiments. In: Proceedings of the Inter-national Conference on Transport Survey Methods, Leura, Australia (2014)
Wardman, M., Batley, R.P., Laird, J.J., Mackie, P.J., Bates, J.: How should business travel time savings bevalued? Econ. Transp. 4(4), 200–214 (2015)
Wheat, P., Batley, R.: Quantifying and decomposing the uncertainty in appraisal values of travel timesavings. Transp. Policy 44, 134–142 (2015)
Richard Batley is Professor of Transport Demand and Valuation at the Institute for Transport Studies (ITS),University of Leeds, UK. He is also Director of ITS Leeds. He is a transport economist by background, andhas particular expertise in the valuation of non-market goods and welfare economics.
John Bates is an Independent Consultant, now based in Berlin, Germany. He specialises in mathematicalmodelling, and has been at the forefront of transportation model development and evaluation methodology,in particular the valuation of time savings and reliability. In addition, he has been a leading figure in thedevelopment of stated preference techniques within the transport field.
Michiel Bliemer is Professor of Transport Network Modelling at the Institute of Transport and LogisticsStudies (ITLS), University of Sydney, Australia. He is a leading expert in transport planning and trafficmanagement methodologies in order to forecast traffic volumes and conditions, as well as methodologyaround stated choice experiments and choice analysis.
Maria Borjesson is Associate Professor of Transport Systems Analysis at the Centre for Transport Studies(CTS), Royal Institute of Technology, Stockholm, Sweden. Her research interests include transport cost-benefit analysis, appraisal and sustainability, transport policy and pricing, and econometrics for valuation ofnon-market goods such as travel time, reliability and security.
Jeremy Bourdon is Consultant at CB&S Limited, London, UK; he was previously at Arup. He establishedhis own consultancy in order to work freelance whilst transitioning his career from programme and projectrisk management of infrastructure to sustainable finance.
Manuel Ojeda Cabral is Research Fellow in Transport Economics and Appraisal at ITS, University ofLeeds, UK. He has experience in various areas of transport economics, including valuation studies, choicemodelling, cost-benefit analysis and efficiency analysis. His main research has focused on the economictheory and the estimation of individuals’ valuation of travel time savings.
Phani Kumar Chintakayala is Senior Research Fellow in Big Data at the Leeds Institute for DataAnalytics (LIDA), University of Leeds, UK. He has experience using stated preference methods and discretechoice models to draw consumer insights for both public and private sector organisations.
Charisma Choudhury is Lecturer in Transport Engineering and Emerging Economies at ITS, University ofLeeds, UK. She is also Deputy Director of the Choice Modelling Centre (CMC) at ITS. Her key researchinterests include behavioural modelling and discrete choice analysis, traffic microsimulation, transportmodelling using big data sources, and transportation in developing countries.
Andrew Daly is Emeritus Professor at ITS, University of Leeds, UK; also Senior Research Fellow at RANDEurope and Visiting Professor at KTH, Stockholm. He is proprietor of ALOGIT Software & Analysis Ltd.His pioneering work on the value of time in the 1970s introduced Random Utility to value of timeestimation, and he was recognised internationally as an expert in the field by 1980. In the 1980s and 1990she contributed to national value of time studies in The Netherlands and the UK.
Thijs Dekker is Lecturer in Transport Economics at ITS, University of Leeds, UK. In both environmentaland transport economics, Thijs has a proven track record of publishing in the field’s leading journals. Hisresearch in the field of discrete choice modelling is on the cutting edge between econometrics,microeconomics and psychology.
Efie Drivyla is Associate Director at Arup, London, UK. Efie has directed and managed a broad range ofprojects varying from research projects and multi-modal and urban/inter-urban studies to local transportation
Transportation
123
studies. She led Arup’s transport planning input into a number of major projects, such as the M1 Widening(junctions 21–30).
Tony Fowkes is Visiting Reader in Transport Econometrics at ITS, University of Leeds, UK. Tony’s
background is in economics and statistics, working briefly in labour economics before joining ITS in 1976,where he worked initially on car ownership forecasting. In 1982 he joined the DfT/BR value of time study,and the associated ESRC study of business travellers value of time (including groundbreaking RP and SPsurveys of employees and a WTP survey of employers).
Stephane Hess is Professor of Choice Modelling and Director of the Choice Modelling Centre (CMC), both
at ITS, University of Leeds, UK. He is also Honorary Professor in Choice Modelling at ITLS, University ofSydney. He is a leading international researcher in the development of advanced discrete choice models forthe analysis of travel behaviour, primarily with the use of stated preference data.
Chris Heywood is Technical Director at Accent, London, UK. With over 30 years’ market research
experience, Chris is a highly skilled manager of complex survey logistics. He has particular expertise inquantitative methods in the transportation market. He is a specialist in the use of stated preferencetechniques and other innovative research approaches.
Daniel Johnson is Senior Research Fellow at ITS, University of Leeds, UK. He is an economist with 24
years’ experience specialising in labour market analysis and transport-economy linkages. Dan has a widerange of modelling experience covering productivity analysis, transport networks and wider economicimpacts of bus provision.
James Laird is Visiting Research Fellow at ITS, University of Leeds, UK. He has 23 years’ experience
within both academic and consultancy environments. His primary research and consultancy interest lies inthe economic appraisal of transport infrastructure. He has a strong interest in cost-benefit analysis, economicimpacts of transport projects, valuation of travel time, wider economic benefits and demand forecasting.
Peter Mackie is Emeritus Professor at ITS, University of Leeds, UK. He is a leading UK academic figure in
transport policy and economics and has specialised in issues relating to transport appraisal and to regulationand deregulation. He has a well-established relationship with the Department for Transport, having been amember of SACTRA for its influential 1992, 1994 and 1999 reports, and also one of the analytical Friendsadvising Sir Rod Eddington on his 2006 report.
John Parkin is Professor of Transport Engineering at the Centre for Transport and Society (CTS),
University of West of England, Bristol, UK. His research interests include the experimental analysis offactors that affect infrastructure design, the assessment and modelling of perceptions of risk and effort asthey influence mode and route choice, and the longitudinal analysis of transport datasets for monitoringpurposes.
Stefan Sanders is UK, Middle East and Africa Rail Business Leader for Arup, London, UK. He has more
than 25 years’ international experience in transport consulting and management, particularly in rail. Stefan ishighly experienced at leading major strategy projects, preparing major business cases, modelling railwayorganisations, advising on rail restructuring (he led Arup’s contribution to the McNulty Rail Value forMoney study) and understanding/advising on the rail regulatory framework.
Rob Sheldon is Managing Director at Accent, London, UK. He has a background in econometrics and over
35 years’ experience of market research consultancy. Rob is an internationally recognised expert in the fieldof stated preference. He was instrumental in introducing the technique to the UK, for a project for BritishRail in the 1970s. He has published extensively and lectured widely on the technique and has managed ordirected more than 250 stated preference projects.
Mark Wardman is Visiting Professor at ITS, University of Leeds, UK. He has over 30 years’ experience of
research into the quantitative analysis of travel behaviour. His first research position was on the UKDepartment for Transport’s pioneering national value of time study in the 1980s. More recently, Mark wasresponsible for the most extensive meta-analyses ever conducted of price elasticities, time elasticities andvalues of time and time related attributes.
Transportation
123
Tom Worsley is Visiting Fellow in Transport Policy at ITS, University of Leeds, UK. Tom joined the UKGovernment Economic Service in 1969 and worked as an economist in a number of different governmentdepartments. Most of his time was spent in the Department for Transport and its predecessors. He heldvarious senior economist posts in the Department between 1988 and May 2011, leading teams responsiblefor developing and improving economic methods.
Transportation
123